RU2604147C1 - Gold-based alloy, hardened with intermetallides containing nickel, (versions) - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to metallurgy of noble metals and alloys, particularly to alloys based on gold, and can be used in electronics, aerospace engineering, jewellery production. According to one version, alloy contains, wt%: gold - 50-95, nickel - 3-5, silicon - 0.5-2, boron - 0.01-1.0, copper - balance, at total content of nickel and silicon not more than 5 %, wherein after thermal or thermo-mechanical processing alloy has a structure, hardened with an intermetallide Ni₂Si. According to a second version alloy contains, wt%: gold - 50-85, cobalt - 11-13.5, aluminium - 1.5-4, boron - 0.01-1.0, copper - balance, at total content of nickel and aluminium, not exceeding 15 %, wherein after thermal or thermo-mechanical processing alloy has a structure hardened with intermetallides Ni₃Al, NiAl, Νi₂Αl₃.

EFFECT: technical result is improved strength properties, especially hardness, while maintaining level of casting properties and ductility.

4 cl, 2 ex

Description

The invention relates to the metallurgy of precious metals, in particular to gold-based alloys intended for use in various industries, in particular for the manufacture of jewelry.

Gold has a unique set of properties that no other metal has. It has the highest resistance to aggressive environments, in electrical and thermal conductivity is second only to silver and copper, the ability of gold to reflect infrared rays is close to 100%. Gold is well soldered and welded under pressure. This combination of useful properties of gold has served its wide use in various industries: electronics, space and aviation technology, etc. However, the bulk of the gold goes to obtain alloys used for the manufacture of jewelry, coins, medals, dentures, gold leaf, decorative coatings.

Technical grade gold in the annealed state has low strength and hardness.

To increase the strength characteristics of gold, alloying of gold with elements contributing to the precipitation hardening of the alloy during subsequent heat treatment is used. One such element is nickel. Alloying gold with nickel increases the hardness of gold by the solid-solution hardening mechanism.

Gold-based alloys are known containing up to 15 wt.% As one of the main alloying components. % nickel (JP 05-195114 A, C22C 5/02, published 03.08.1993; RU 2156824 C1, C22C 5/02, published 09.27.2000; RU 2151211 C1, C22C 5/02, 06.20.2000; RU 2361942 C1, C22C 5/02, 07/20/2009). A disadvantage of the known alloys is the insufficient level of mechanical properties caused by heat treatment with solid solution hardening.

Closest to the proposed invention is an alloy containing, by weight. %: 56-60 gold, 3-5 nickel, 7.5-8.5 silver, 0.8-1.2 titanium, 0.01-0.03 boron, 0.001-0.003 calcium, copper - the rest (RU 2326954 C2, C22C 5/02, 06/20/2008). The disadvantage of alloys is their low hardness.

The problem to which the invention is directed, is to create an alloy based on gold with the optimal combination of physical and mechanical properties.

The technical result of the invention is to increase the strength properties, especially hardness, while maintaining the level of casting properties and ductility.

The technical result is achieved in that the alloy based on gold, containing Nickel, copper, boron, additionally contains silicon in the following ratio of components, wt. %:

gold 50-95 nickel 3-5 silicon 0.5-2 boron 0.01-1.0 copper the rest, with the total content  nickel and silicon up to 5%,

after thermal or thermomechanical treatment, the alloy has a structure hardened by intermetallic Ni ₂ Si.

According to another embodiment of the invention, the technical result is achieved in that the gold-based alloy containing nickel, copper, boron, additionally contains aluminum in the following ratio of components, wt. %:

gold 50-85 nickel 11-13.5 aluminum 1,5-4 boron 0.01-1.0 copper the rest, with the total content  nickel and aluminum up to 15%,

after thermal or thermomechanical treatment, the alloy has a structure hardened by intermetallic compounds Ni ₃ Al, NiAl, Ni ₂ Al ₃ .

Alloys in both cases may additionally contain at least one element selected from the group containing up to 30 wt. % palladium, up to 30 wt. % platinum, up to 30 wt. % silver, up to 10 wt. % indium, up to 10 wt. % gallium.

The invention consists in the following.

Dispersion hardening during low-temperature annealing leads to an increase in hardness with a simultaneous decrease in ductility, which makes it possible to increase the wear resistance of alloys.

The claimed alloys have the ability to harden during thermal or thermomechanical processing, while they have a relatively low melting point and good processability during casting, hot and cold deformation.

The hardening of gold-based alloys is based on the effect of dispersion hardening. The heat treatment of precipitation hardening alloys consists in heating them to form a supersaturated solid solution, followed by rapid cooling (quenching) and aging. As a result of such heat treatment, the solid solution decomposes with the release of nanophase particles of phases - hardeners. The strengthening effect is achieved due to the released intermetallic compounds. The difference from hardeners of a different composition is significant both in the method of formation and in the structure, nature of the melting points, kinetics of decomposition of the solid solution, the effect of hardening and its stability. The method of hardening gold-based alloys involves introducing into the alloy two components that form a chemical compound. Nickel and silicon are used as such components in one embodiment of the invention, and nickel and aluminum in another embodiment. Their quantitative content in alloys is determined by the stoichiometric ratio necessary for the formation of Ni ₂ Si and Ni ₃ Al, NiAl, Ni ₂ Al ₃ intermetallics during subsequent thermal or thermomechanical treatment.

Being a deoxidizing agent, boron in an amount of 0.01-1% reduces the effect of oxygen during the smelting of alloys, reduces the loss of alloying components on fumes and reduces the grain size, while increasing the fluidity of the melt.

Copper increases the hardness of the gold alloy, while maintaining ductility and ductility. The increase in copper content in the alloy above 40 wt. % leads to a decrease in the strength characteristics of the alloy, and also lowers its anticorrosion properties.

The hardening of gold-based alloys containing nickel and silicon or aluminum is based on the dispersion hardening mechanism realized by thermal or thermomechanical treatment. Heat treatment consists in heating the alloy to form a supersaturated solid solution, followed by rapid cooling - quenching and aging, as a result of which the solid solution decomposes with the release of strengthening nanophase particles Ni ₂ Si or Ni ₃ Al, NiAl, Ni ₂ Al ₃ .

During thermomechanical treatment between hardening and aging, or after aging, plastic deformation is carried out.

Examples of the invention.

Example 1. An alloy of the following chemical composition was obtained: 75% Au, 4% Ni, 1% Si, 19.5% Cu, up to 0.5% B, impurities not more than 0.1%.

The charge materials were loaded into a crucible made of artificial sapphire, which was placed in a heated graphite crucible. Melting was carried out in a vacuum furnace of resistive heating. The melting temperature was 1250 ° C. Cylindrical ingots with a diameter of 30 mm and a height of 8 mm were obtained. To improve the casting properties of the alloy and increase fluidity, boron was introduced. In addition, metallographic analysis showed a decrease in grain size. The introduction of copper allowed us to obtain a saturated "red" color of interesting shades.

To increase the hardness of the ingot, it was subjected to heat treatment according to the scheme: heating the alloy to a temperature of 920 ° C, ensuring the formation of a supersaturated solid solution, holding it at this temperature for one hour, and quenching in water from this temperature to a temperature of less than 100 ° C. After that, aging was carried out at a temperature of 480 ° C for one hour.

The hardness of the alloy after heat treatment was 270 HB, which was almost two times higher than the hardness of cast alloys with solid solution hardening.

Example 2. An alloy of the following chemical composition was obtained: 75% Au, 12% Ni, 3% Al, 9.9% Ag, up to 0.1% B, impurities not more than 0.1%.

Melting was carried out analogously to example 1 at a temperature of 1250 ° C. The alloy turned out to be a beautiful "white" shade with a uniform metallic luster.

After holding the alloy at a temperature of 940 ° C for one hour, water quenching was carried out. Aging was carried out at a temperature of 470 ° C with exposure for two hours.

The alloy obtained after heat treatment had a hardness of 260 HB, compared with cast alloys, whose hardness was 125 HB, while maintaining casting properties and ductility.

Thus, the claimed alloys have high casting properties. They have high hardness combined with plasticity and interesting color shades, which makes it possible to make jewelry with high consumer properties from them.

Claims (4)

1. Gold-based alloy containing nickel, copper and boron, characterized in that it additionally contains silicon in the following ratio of components, wt.%:
gold 50-95 nickel 3-5 silicon 0.5-2 boron 0.01-1.0 copper the rest, with the total content nickel and silicon up to 5%,
after thermal or thermomechanical treatment, the alloy has a structure hardened by intermetallic Ni ₂ Si. 2. The alloy according to claim 1, characterized in that it further comprises at least one element selected from the group consisting of up to 30 wt.% Palladium, up to 30 wt.% Platinum, up to 30 wt.% Silver, up to 10 wt.% Indium, up to 10 wt.% Gallium. 3. An alloy based on gold containing nickel, copper and boron, characterized in that it additionally contains aluminum in the following ratio of components, wt.%:
gold 50-85 nickel 11-13.5 aluminum 1,5-4 boron 0.01-1.0 copper the rest, with the total content nickel and aluminum up to 15%,
after thermal or thermomechanical treatment, the alloy has a structure hardened by intermetallic compounds Ni ₃ Al, NiAl, Ni ₂ Al ₃ . 4. The alloy according to claim 3, characterized in that it further comprises at least one element selected from the group consisting of up to 30 wt.% Palladium, up to 30 wt.% Platinum, up to 30 wt.% Silver, up to 10 wt.% Indium, up to 10 wt.% Gallium.